R-Spondin potentiates Wnt/ß-catenin signaling through orphan receptors LGR4 and LGR5.

The Wnt/ß-catenin signaling pathbway controls many important biological processes. R-Spondin (RSPO) proteins are a family of secreted molecules that strongly potentiate Wnt/ß-catenin signaling, however, the molecular mechanism of RSPO action is not yet fully understood. We performed an unbiased siRNA screen to identify molecules specifically required for RSPO, but not Wnt, induced ß-catenin signaling. From this screen, we identified LGR4, then an orphan G protein-coupled receptor (GPCR), as the cognate receptor of RSPO. Depletion of LGR4 completely abolished RSPO-induced ß-catenin signaling. The loss of LGR4 could be compensated by overexpression of LGR5, suggesting that LGR4 and LGR5 are functional homologs. We further demonstrated that RSPO binds to the extracellular domain of LGR4 and LGR5, and that overexpression of LGR4 strongly sensitizes cells to RSPO-activated ß-catenin signaling. Supporting the physiological significance of RSPO-LGR4 interaction, Lgr4-/- crypt cultures failed to grow in RSPO-containing intestinal crypt culture medium. No coupling between LGR4 and heterotrimeric G proteins could be detected in RSPO-treated cells, suggesting that LGR4 mediates RSPO signaling through a novel mechanism. Identification of LGR4 and its relative LGR5, an adult stem cell marker, as the receptors of RSPO will facilitate the further characterization of these receptor/ligand pairs in regenerative medicine applications.

Related transcriptional enhancer factor 1 increases endothelial-dependent microvascular relaxation and proliferation.

OBJECTIVE: Related transcriptional enhancer factor 1 (RTEF-1) is a key transcriptional regulator in endothelial function. In this study, we investigated a possible role for RTEF-1 in the regulation of microvascular relaxation and the underlying mechanism involved. Activation of fibroblast growth factor receptor 1 (FGFR1) by FGFs increases vasodilation, although transcriptional control of the molecular mechanisms underlying FGFR1 is still unclear. MATERIALS AND METHODS: We demonstrated that RTEF-1 stimulated FGFR1 expression at the transcriptional level, specifically an area including Sp1 elements, as evidenced by promoter assays. Additionally, RTEF-1 increased FGFR1 mRNA and protein expression in vitro and in VE-cadherin-promoted RTEF-1 (VE-Cad/RTEF-1) transgenic mice, whereas RTEF-1 siRNA blocked the upregulation of FGFR1 expression. Furthermore, increased endothelial-dependent microvessel relaxation was observed in the coronary arteries of VE-Cad/RTEF-1 mice, and increased proliferation was observed in RTEF-1-overexpressing cells, both of which correlated to increased FGF/FGFR1 signaling and endothelial nitric oxide synthase (eNOS) upregulation. Our results indicate that RTEF-1 acts as a transcriptional stimulator of FGFR1 and is involved in FGF pathways by increasing microvessel dilatation via eNOS. CONCLUSIONS: These findings suggest that RTEF-1 plays an important role in FGFR1- stimulated vasodilatation. Understanding the effect of RTEF-1 in microvessel relaxation may provide beneficial knowledge in improving treatments in regards to ischemic vascular disorders.

RTEF-1, an upstream gene of hypoxia-inducible factor-1α, accelerates recovery from ischemia.

The amount of available hypoxia-inducible factor (HIF)-1α has been considered to be largely a consequence of post-translational modification by multiple ubiquitin-proteasome pathways. However, the role of transcriptional regulation of HIF-1α is less certain, and the mechanisms of transcriptional regulation of HIF-1α require further investigation. Here we report that related transcriptional enhancer factor-1 (RTEF-1), a member of the TEF transcriptional factor family, transcriptionally regulates the HIF-1α gene under normoxic and hypoxic conditions. The expression of HIF-1α mRNA was decreased in endothelial cells in which RTEF-1 was knocked down with siRNA. Sequential deletional analysis of the HIF-1α promoter revealed that the MCAT-like element in the HIF-1α promoter was essential for HIF-1α transcription. Binding of RTEF-1 to the MCAT-like element was confirmed by ChIP. Treatment of endothelial cells with a HIF-1 inhibitor resulted in retardation of RTEF-1-induced proliferation and tube formation. Moreover, increased HIF-1α expression was observed in transgenic mice expressing RTEF-1 under the VE-cadherin promoter (VE-Cad/RTEF-1). VE-Cad/RTEF-1 mice subjected to hindlimb ischemia demonstrated increased levels of HIF-1α, accelerated recovery of blood flow, and increased capillary density compared with littermate controls. These results identify RTEF-1 as a regulator of HIF-1α transcription, which results in up-regulation of HIF-1α and acceleration of recovery from ischemia.

The endothelium-dependent effect of RTEF-1 in pressure overload cardiac hypertrophy: role of VEGF-B.

AIMS: Related transcription enhancer factor-1 (RTEF-1) has previously been demonstrated to play an important role in both endothelial cells and cardiomyocytes. However, the function of RTEF-1 in the communication between these two adjacent cell types has not been elucidated. METHODS AND RESULTS: We have found that endothelium-specific RTEF-1 transgenic mice (VE-Cad/RTEF-1) developed significant cardiac hypertrophy after transverse aortic constriction surgery, as evidenced by an increased ratio of heart weight to tibia length, enlarged cardiomyocyte size, thickened left ventricular wall and elevated expression of hypertrophic gene markers, with up-regulation of vascular endothelial growth factor B (VEGF-B). Additionally, VEGF-B was increased in endothelial cells from VE-Cad/RTEF-1 mice, as well as in endothelial cells with forced RTEF-1 expression (HMEC-1/RTEF-1), and coincidentally decreased when RTEF-1 was deficient in HMEC-1. Using chromatin immunoprecipitation and luciferase assays, we found that RTEF-1 increased VEGF-B promoter activity through a direct interaction. Hypertrophy-associated genes and protein synthesis were up-regulated in cardiomyocytes that were incubated with conditioned medium from HMEC-1/RTEF-1 and the endothelial cells of VE-Cad/RTEF-1 mice. This effect could be abrogated by treating the myocytes with VEGF-B small interfering RNA and extracellular signal-regulated kinase 1/2 inhibitor. CONCLUSION: Our data demonstrated that increased RTEF-1 in endothelial cells upregulates VEGF-B, which is able to stimulate hypertrophic genes in cardiomyocytes. These results suggest that the RTEF-1-driven increase of VEGF-B plays an important role in communication between the endothelium and myocardium.

Hyperglycemia attenuates angiogenic capability of survivin in endothelial cells.

Survivin, an anti-apoptotic protein, can be induced by hypoxia and contributes to angiogenic activity in endothelial cells. To determine the potential mechanism of survivin in endothelial dysfunction caused by hyperglycemia in diabetes, we evaluated the role of survivin in hyperglycemia and its effect on endothelial homeostasis. We demonstrated that an increase of D-glucose was sufficient to down-regulate survivin expression, impacting survivin's angiogenic role in endothelial cells. We additionally showed that survivin expression was increased in response to hypoxia yet this reaction was mitigated when the endothelial cells were in hyperglycemic conditions prior to hypoxia. Hyperglycemia also affected survivin-related proliferation and migration of endothelial cells and increased the number of apoptotic cells. In the ischemic porcine myocardium, the expression of survivin was induced. Moreover, survivin expression in the aorta, myocardium, and isolated endothelial cells was attenuated in a porcine model of diabetes in comparison to non-diabetes, which correlated negatively with the levels of fasting blood sugars and positively with territory perfusion. These results demonstrate that hyperglycemia critically alters survivin expression in vitro and in vivo, which leads to attenuation of angiogenic activity and impacts endothelial metabolism.

Radiation enhances the invasive potential of primary glioblastoma cells via activation of the Rho signaling pathway.

Glioblastoma multiforme (GBM) is among the most treatment-refractory of all human tumors. Radiation is effective at prolonging survival of GBM patients; however, the vast majority of GBM patients demonstrate progression at or near the site of original treatment. We have identified primary GBM cell lines that demonstrate increased invasive potential upon radiation exposure. As this represents a novel mechanism by which radiation-treated GBMs can fail therapy, we further investigated the identity of downstream signaling molecules that enhance the invasive phenotype of irradiated GBMs. Matrigel matrices were used to compare the extent of invasion of irradiated vs. non-irradiated GBM cell lines UN3 and GM2. The in vitro invasive potential of these irradiated cells were characterized in the presence of both pharmacologic and dominant negative inhibitors of extracellular matrix and cell signaling molecules including MMP, uPA, IGFR, EGFR, PI-3K, AKT, and Rho kinase. The effect of radiation on the expression of these signaling molecules was determined with Western blot assays. Ultimately, the in vitro tumor invasion results were confirmed using an in vivo 9L GBM model in rats. Using the primary GBM cell lines UN3 and GM2, we found that radiation enhances the invasive potential of these cells via activation of EGFR and IGFR1. Our findings suggest that activation of Rho signaling via PI-3K is required for radiation-induced invasion, although not required for invasion under physiologic conditions. This report clearly demonstrates that radiation-mediated invasion is fundamentally distinct from invasion under normal cellular physiology and identifies potential therapeutic targets to overcome this phenomenon.

Survivin enhances radiation resistance in primary human glioblastoma cells via caspase-independent mechanisms.

The observed radioresistance of human glioblastoma multiforme (GBM) poses a major challenge, which, if overcome, may lead to significant advances in the management of this patient population. There is accumulating evidence from correlative studies that Survivin expression is associated with increased malignant potential of human gliomas. The purpose of this study was to investigate whether Survivin plays a direct role in mediating radiation resistance in primary human glioma cell lines, and, if so, investigating the underlying mechanisms. Our panel of GBM cell lines included two that were relatively radiation resistant (GM20 and GM21) and two that were more radiation sensitive (GM22 and GM23), which demonstrated differential levels of Survivin expression between the two groups. Through the use of adenoviral vectors containing either dominant-negative (pAd-S(T34A)) or wild-type Suvrivin (pAd-S(WT)), we were able to inactivate or overexpress Survivin, respectively. Our findings suggest that Survivin plays a critical role in mediating radiation resistance in primary GBM cells, in part through suppression of apoptotic cell death via a caspase-independent manner. We have identified novel mechanisms by which Survivin may enhance tumor cell survival upon radiation exposure such as regulation of double-strand DNA break repair and tumor cell metabolism, which were most evident in the radiation-resistant cell lines. These differences in Survivin function both in radiation-resistant vs radiation-sensitive cell lines and in the presence vs absence of radiation exposure warrant further investigation and highlight potentially important mechanisms of radiation resistance in these tumors.